DE1149809B - Stabilized power rectifier circuit - Google Patents

Description

Stabilized Power Rectifier Circuit. Patent 1077,318 relates to a stabilized mains rectifier circuit for generating one of mains voltage fluctuations and load fluctuations with substantially independent DC output voltage an idling transformer in the magnetically oversaturated area and a capacitor connected in parallel to a transformer winding, with in Series with the primary winding of the transformer only when the rectifier circuit is fully loaded saturated choke coil and in the output circuit of the rectifier circuit a adjustable choke coil is provided. It is therefore a circuit arrangement in which a resonant circuit tuned approximately to the mains frequency with an oversaturated Iron core inductance with an essentially unsaturated iron core inductance is electrically connected in series.

Such circuit arrangements have the property, the influence to compensate for fluctuations in the mains voltage on the output voltage within wide limits. In addition, additional circuitry or design measures within such arrangements also internal voltage drops, which are normally associated with increasing current load increase, compensated so that the output voltage is also largely independent of load fluctuations. According to patent 1077 318 this is achieved by the fact that the primary winding of the idle is magnetically oversaturated area working transformer upstream choke coil sized is that this is only saturated when the rectifier circuit is fully loaded, and that An adjustable choke coil is provided in the output circuit of the rectifier circuit is.

The invention is based on the object of providing the circuit arrangement the patent 1077 318 to simplify and also to improve with smaller dimensions. According to the invention in the stabilized power rectifier circuit according to the Patent 1077 318 between the primary and secondary winding of the transformer a magnetic Stray flux path provided with increased magnetic resistance such that a part the magnetic flux can enforce one winding to the exclusion of the other, and the choke coil is only saturated when the rectifier circuit is fully loaded laid in the primary winding of the transformer and finally the capacitor a secondary winding of the transformer to form a resonance circuit in parallel switched. The stray flux path creates a certain decoupling between the primary and secondary winding achieved, creating magnetic circuits with different saturation be created, which the inclusion of the rectifier circuit only at full load enable saturated choke in the primary winding of the transformer.

The circuit can be designed so that the primary and secondary windings of the transformer are arranged at a distance on a magnetic core and of at least an E-shaped magnet yoke are gripped, the center leg between the Windings protrudes and forms an air gap with the magnetic core. The circuit can also be designed so that the primary and secondary windings are spaced apart on the center leg a jacket transformer core are arranged and that between the windings, namely in the space between the middle limb and the outer limb, magnetic cores are inserted in such a way that air gaps remain between legs and cores. A particularly favorable arrangement is obtained when the primary and secondary windings of the transformer depending on at least one half part of a cut ribbon core a magnetic sheet with a preferred magnetic direction running in the longitudinal direction are arranged and the legs of the cut ribbon core halves with their end faces on the side of a laminated core serving as a magnetic stray flux path, namely on the front edges of their perpendicular to the longitudinal direction magnetic Magnetic sheets exhibiting preferred direction, applied essentially without an air gap are. In this case, an arrangement with particularly good efficiency is achieved, which also requires little effort. In particular, the effort of magnetic material considerably.

The invention is based on the drawing of several exemplary embodiments explained in more detail. In the drawing, FIGS. 1 and 2 show a circuit arrangement below Use of cut tape cores for the circuit according to the invention Transformer, FIGS. 3 and 4, two further embodiments of the transformer core using stamped transformer sheets, whereby the increased resistance of the Magnetic stray flux path is achieved by air gaps, Fig. 5 is a circuit diagram the circuit according to the invention with one in the output circuit of the rectifier circuit arranged adjustable choke coil, Fig. 6 shows a special embodiment of the in Fig. 5 adjustable choke coil, Fig. 7 is a circuit diagram of an opposite 5 modified circuit in which the secondary alternating current of the transformer is fed to the rectifier bridge via a choke coil, Fig. 8 is a graph Representation of the dependency of the DC output voltage on the mains voltage and the load, namely with a circuit according to FIG. 5 (solid curves) and with a short-circuited choke coil in the direct current circuit (dashed curves).

5 and 7 are two embodiments of the invention Circuit shown, the core of the transformer used only schematically is indicated. The primary and secondary windings of the transformer are preferred 1 and 2 arranged on the transformer core. In. these figures are with 10 to 13 denotes four cut ribbon core halves, which are attached to the straight core part 14 are set. The cut ribbon core halves 10 to 13 are made in a known manner manufactured. It becomes a magnetic sheet with a magnetic sheet running in the longitudinal direction Preferred direction wound onto a mandrel, for example, and the individual Sheet metal layers glued together after an annealing process and the winding produced in this way split in the middle. The magnetic flux flowing through the core halves penetrates As a result, the individual sheets are always in the preferred magnetic direction.

The straight core part 14 consists of lamellas stacked one on top of the other, which also have a preferred magnetic direction, namely this preferred direction runs perpendicular to the longitudinal direction of the core part 14 , Leg 12 a of the core part 12, leg 12 b of the core part 12, core 14, leg 10 b of the core part 10.

Leg 11 a of the core part 11, core 14, leg 13 a of the core part 13, leg 13 b of the core part 13, core 14, leg II b of the core part 11. In In both magnetic circuits, the magnetic flux runs exclusively in the magnetic one Preferred direction of the various slats.

The primary winding 16 of the transformer is plugged onto the legs 10 b and 11 a of the core parts 10 and 11, while the secondary winding 17 is plugged onto the legs 12 b and 13 a of the core parts 12 and 13. The individual core parts 10 to 13 are attached to the side of the core 14 in such a way that the end faces of the legs rest against the end edges of the lamellas forming the core 14 essentially without forming an air gap. The individual lamellas of the core 14 are held together by rivets 18, which can be made of brass, for example. Between the end faces of the individual core legs and the core 14, a thin electrically insulating layer is provided, which is intended to prevent the occurrence of eddy currents. The entire device is held together by the tensioning strap 15 .

The increased resistance of the magnetic core serving as a leakage flux path 14 results from the fact that the preferred magnetic direction of the individual sheets perpendicular to the longitudinal direction of the core, while the leakage flux extends the core interspersed in its longitudinal direction.

The core 14 can be along the line 19, so in a magnetically neutral Zone, be divided without affecting the magnetic properties. Of the The transformer shown in Fig. 1 and Fig. 2 then consists of two identical types Share. Instead of two parts, the transformer can of course also have just one Core part, thus approximately consisting of parts 10, 12, 14 included.

The core of the transformer can also be constructed according to FIG. 3, in which the primary winding 20 and the secondary winding 21 are arranged at a distance on a core 22 and are encompassed by two E-shaped yoke parts 23 and 24. The yoke part 23 rests against the core 22 with the end faces of its legs 23 a and 23 b and the yoke part 24 with the end faces of its legs 24 a and 24 b. The magnetic stray flux path is formed by the middle legs 23c and 24c, between whose end faces and the core 22 air gaps remain, which cause the increased resistance of the stray flux path.

The transformer can also be designed according to FIG. This is a jacket core with a middle limb 30 and two outer limbs 31 and 32. On the middle limb 30, the primary winding 33 and the secondary winding 34 are arranged at a distance. In the space between the primary winding 33 and the secondary winding 34 or between the middle limb 30 and the outer limbs 31 and 32, two magnetic cores 35 and 36 composed of magnetic sheets are arranged. Magnetically non-conductive layers 37 are provided between these cores 35 and 36 and the legs of the transformer core, through which magnetic air gaps are formed which cause the increased resistance of the leakage flux path.

In the circuit diagram of FIG. 5, 40 is the main core of the transformer and indicated by 41 the magnetic stray flux path. 42 is the primary winding and 43 the secondary winding, which has a center tap 44. With the winding ends the capacitor 45 is connected. It forms together with the secondary winding 43 a resonance circuit. From the winding end 46 and the center tap 44 the rectifier bridge 47 is fed, the choke coil 48 in its output circuit is switched. This choke coil 48 contains a number of taps, with their Help the inductance of the choke is adjustable.

Due to the magnetic leakage path, the magnetic flux is in the transformer core given the opportunity to enforce one winding to the exclusion of the other. The secondary voltage stabilized with the resonance circuit capacitor 45 can thereby be used even with fluctuations in the magnetic flux in the primary excitation winding the stray flux path 41 largely maintain its own excitement. For the mode of action It is essential that the magnetic resistance of the main iron path is smaller than that normal magnetic resistance of the leakage flux path. It has been shown that a particularly good utilization of the magnetic material is possible if a transformer according to FIGS. 1 and 2 is used. In this case it won't only an improved efficiency of the circuit is achieved, but it can also do the Material required for the transformer can be reduced considerably.

The choke coil 48 arranged in the direct current output circuit also compensates for the effects of load fluctuations. Adjustment of the reactor 48 can be accomplished in a number of ways. Instead of the choke coil 48 with taps shown in FIG. 5, a choke coil 51 according to FIG. 6 can be connected to the terminals 49 and 50. A resistor 52, the resistance value of which can be changed, is connected in parallel with this choke coil 51.

FIG. 7 shows a circuit modified compared to the circuit according to FIG. 5, in which a variable choke coil 53 is additionally provided in the secondary alternating current circuit of the transformer. With the help of this choke coil, it is also possible to compensate for the changes in the secondary voltage due to changes in the load. The choke coil 53 is therefore also effective without a downstream rectifier bridge 47 and already brings about an improvement in the voltage constancy of the secondary alternating voltage through load changes. The variability of the choke coil 53 can also be achieved in other ways instead of taps. For example, instead of the choke coil 53, a transducer can be used, the inductance of which is changed by means of an adjustable bias.

Fig. $ Shows a graphical representation of the dependency of the DC output voltage the primary voltage as well as the load. The solid curves show the Dependency when the choke coil 48 is switched on, while those shown in dashed lines Curves show the dependency without this choke coil 48. It can be clearly seen that up to a certain load by the switched-on throttle 48 is essentially one Output DC voltage independent of mains voltage fluctuations and load fluctuations is achieved.

Claims (5)

PATENT CLAIMS: 1. Stabilized power rectifier circuit for generation one of the mains voltage fluctuations and load fluctuations essentially independent DC output voltage with an open circuit in the magnetically oversaturated area working transformer and with one to form a resonance circuit to one Transformer winding in parallel capacitor, being in series with the Primary winding of the transformer only when the rectifier circuit is fully loaded saturated choke coil and in the output circuit of the rectifier circuit a adjustable choke coil is provided according to patent 1077 318, characterized in that that between the primary and secondary winding of the transformer there is a magnetic stray flux path is provided with increased magnetic resistance such that a part of the magnetic River can enforce a winding to the exclusion of the other that the first when the rectifier circuit is fully loaded, the choke coil is saturated in the primary winding of the transformer is installed and that the capacitor is a secondary winding of the transformer is connected in parallel. 2. Circuit according to claim 1, characterized characterized in that the primary and secondary windings of the transformer are spaced apart are arranged on a magnetic core and of at least one E-shaped magnetic yoke are encompassed, the middle leg protrudes between the windings and with the Magnetic core forms an air gap. 3. Circuit according to claim 1, characterized in that that the primary and secondary windings are spaced apart on the center leg of a sheathed transformer core are arranged and between the windings, in the space between Central limbs and outer limbs, magnetic cores are inserted in such a way that between Leg and core air gaps remain. 4. Circuit according to claim 1, characterized characterized in that the primary and secondary winding of the transformer each at least a half part of a cut tape core made of a magnetic sheet with in the longitudinal direction extending preferred direction are arranged, wherein the end faces of the cut tape core halves on the side of a laminated core serving as a magnetic stray flux path, namely on the front edges of their preferred magnetic direction perpendicular to the longitudinal direction having magnetic sheets, are attached essentially without an air gap. 5. Circuit according to one or more of claims 1 to 4, characterized in that in the secondary AC circuit of the transformer has a variable choke coil connected in series is arranged.